{
  "docId": "019dd923-5de0-76bd-a169-f222b31ea833",
  "docSlug": "0e5e77bd2a5ace9c",
  "documentTitle": "Hydrogen applications and business models",
  "authorId": "Kearney",
  "authorName": "Kearney",
  "documentKindSlug": "consulting-deck",
  "documentKindLabel": "Consulting deck",
  "sourceTypeSlug": "strategy_consulting",
  "sourceTypeLabel": "Strategy consulting",
  "presentationDate": null,
  "orientation": "landscape",
  "aspectRatio": 1.778,
  "pageNumber": 113,
  "pageCount": 192,
  "prevPage": 112,
  "nextPage": 114,
  "slideType": "industry_trends",
  "function": "present_solution",
  "density": "overcrowded",
  "nDataPoints": 12,
  "notes": "Includes a technical diagram of a domestic fuel cell and a comparative table of technical/financial specs.",
  "elementsJson": [
    "bullet_list",
    "photo",
    "comparison_table",
    "other"
  ],
  "metadataConfidence": 1,
  "imagePath": null,
  "slideHref": "/slides/019dd923-5de0-76bd-a169-f222b31ea833/113",
  "deckHref": "/decks/019dd923-5de0-76bd-a169-f222b31ea833",
  "deckJsonHref": "/decks/019dd923-5de0-76bd-a169-f222b31ea833.json",
  "deckAnchorHref": "/decks/019dd923-5de0-76bd-a169-f222b31ea833#slide-113",
  "components": [
    {
      "bbox": null,
      "kind": "callout",
      "text": "By 2030, final energy prices for hydrogen would need to be in the range of $1.50 to $3.00 per kg to compete with natural gas and electricity.",
      "attrs": null,
      "subkind": null,
      "toolName": "Visual emphasis",
      "toolSlug": "visual-emphasis",
      "confidence": null,
      "componentId": "019dd952-0a6a-74c9-8aa8-127bdf728060",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.3,
        "w": 0.15,
        "x": 0.72,
        "y": 0.115
      },
      "kind": "image",
      "text": "Domestic fuel cell diagram",
      "attrs": null,
      "subkind": "illustration",
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "fef5bd1d-297b-4912-b24c-23b561db28e6",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": null,
      "kind": "metric",
      "text": "Cost competitiveness: $1.50 to $3.00",
      "attrs": null,
      "subkind": "primary",
      "toolName": "Quantification",
      "toolSlug": "quantification",
      "confidence": null,
      "componentId": "019dd952-0a6a-74c9-8aa8-14af69225c94",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.4,
        "w": 0.3,
        "x": 0.28,
        "y": 0.11
      },
      "kind": "paragraph",
      "text": "A 100% hydrogen network could be coupled with fuel cells and other systems at the end user's consumption site to meet demand for heating, cooling, and electricity. Worldwide, there are 4,500 km of pipelines, mostly operated by hydrogen producers. Investment costs are high but may pay off only with large shipping volume of hydrogen. H2 transported through pipeline could also find other applications, such as refueling stations and industrial use. Developing micro-networks with decentralized production sources could reduce infrastructure costs. By 2030, final energy prices for hydrogen would need to be in the range of $1.50 to $3.00 per kg to compete with natural gas and electricity.",
      "attrs": null,
      "subkind": "paragraph",
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "a6909598-d026-4428-ac06-dde084ff84ef",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.03,
        "w": 0.4,
        "x": 0.28,
        "y": 0.95
      },
      "kind": "source-note",
      "text": "Sources: \"The Future of Hydrogen,\" International Energy Agency, June 2019; Hydrogen Europe; Kearney Energy Transition Institute analysis",
      "attrs": null,
      "subkind": null,
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "33851c07-a840-46a3-9747-f2c1f2b80f15",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.35,
        "w": 0.3,
        "x": 0.65,
        "y": 0.55
      },
      "kind": "table",
      "text": "Comparison of Fuel cell m-CHP vs Gas boiler",
      "attrs": null,
      "subkind": "data",
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "045b7173-48ca-4057-905d-871a185c252b",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.2,
        "w": 0.3,
        "x": 0.28,
        "y": 0.6
      },
      "kind": "table",
      "text": "H2 Market trends table",
      "attrs": null,
      "subkind": "data",
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "fbc4d4f3-7d28-42f8-a09e-7ad1863c20bc",
      "frameworkName": null,
      "frameworkSlug": null
    },
    {
      "bbox": {
        "h": 0.35,
        "w": 0.22,
        "x": 0.03,
        "y": 0.05
      },
      "kind": "title",
      "text": "A 100% H2 network can also be considered for providing energy to end users through fuel cells, co-generation, or other hybrid systems",
      "attrs": null,
      "subkind": "action-title",
      "toolName": null,
      "toolSlug": null,
      "confidence": null,
      "componentId": "954b4f4a-5f59-4934-abd2-6f083a3375f3",
      "frameworkName": null,
      "frameworkSlug": null
    }
  ],
  "metrics": [],
  "tools": [],
  "frameworks": [],
  "arcBeats": [],
  "loops": [],
  "imagePathAlt": null,
  "thumbSrc": null,
  "thumbSrcAlt": null,
  "locked": true
}